EP3333295A1

EP3333295A1 - Thermal insulating structure

Info

Publication number: EP3333295A1
Application number: EP17205384.5A
Authority: EP
Inventors: Julie Caroline Gretton; John Rutledge; Stephen John Russell; Vera CHETTY; Matthew James TIPPER
Original assignee: Adidas AG
Current assignee: Adidas AG
Priority date: 2016-12-06
Filing date: 2017-12-05
Publication date: 2018-06-13
Anticipated expiration: 2037-12-05
Also published as: JP6902459B2; DE102016224251A1; CN108149384A; US10815592B2; US20180155859A1; DE102016224251B4; EP3333295B1; CN108149384B; JP2018135628A

Abstract

The present invention relates to a thermal insulating structure comprising at least one baffle, an article of wear and a sleeping bag comprising such a thermal insulating structure and to a method for manufacturing such a thermal insulating structure. In one embodiment, the baffle comprises a plurality of natural and / or synthetic down fibers and a plurality of low-melt fibers, wherein the low-melt fibers have been melted to the natural and / or synthetic down fibers by heating inside the baffle.

Description

1. Technical field

The present invention relates to a thermal insulating structure comprising at least one baffle, an article of wear and a sleeping bag comprising such a thermal insulating structure and to a method for manufacturing such a thermal insulating structure.

2. Prior art

Clusters of down feathers are well known as warm, lightweight and packable material for filling into garments such as a jacket or into a duvet for winter. The loose structure of down feathers traps air, which helps to insulate a wearer against heat loss. If well cared for, they retain their loft up to three times longer than do most synthetics. However, when down feathers are wet, their thermal properties are virtually eliminated. Down feathers form clumps if exposed to dampness or moisture, and will mildew if left damp. In addition, they will absorb and retain odors.
As a counter measure in order to mimic the thermal properties of down feathers, combinations of synthetic fibers with low-melt fibers are known in the art. Various methods for manufacturing thermal insulating materials are known from AU2003204527 A1 , EP0279677 A2 , US 2005/0124256 A1 , EP0600844 A1 , US 2014/0193620 A1 and from a publication of Dahiya et al. (c.f. e.g. http://www.engr.utk.edu/mse/Textiles/Melt%20Blown%20Technology.htm).
The US 2006/0076106 A1 discloses a process for making a high loft, nonwoven material by providing either natural and / or synthetic fibers, providing a low-melt binder fiber, mixing the low-melt binder fiber and the natural and/or synthetic fibers to form a web, cross-lapping the web, drafting the web with a drafter, heating the drafted web to a temperature sufficient to melt the low-melt binder fibers, and cooling the web thereby forming a structural nonwoven material.
Further prior art is disclosed in DE 602 25 915 T2 , DE 10 2014 002 060 A1 , WO 2016/035 255 A1 , JP S61 - 213 087 A , US 2002 / 0 034 637 A1 , US 4 167 604 A , DE 21 39 023 A , WO 96/ 41 560 A1 , DE 10 2008 035 621 A1 and CN 204 510 665 U .
However, such thermal insulating materials have limitations and may not be able to provide thermal and lightweight properties to an acceptance level. This is especially true for textiles, e.g. of jackets, having a plurality of baffles, in which the synthetic fibers and / or down fibers are placed.
Therefore, the underlying problem of the present invention is to provide an improved structure for providing improved thermal and lightweight properties in order to at least partly overcome the above mentioned deficiencies of the prior art.

3. Summary of the invention

This problem is at least partly solved by a thermal insulating structure including at least one baffle, wherein the baffle comprises a plurality of natural and / or synthetic down fibers and a plurality of low-melt fibers, wherein the low-melt fibers have been melted to the natural and / or synthetic down fibers by heating inside the baffle.
Whereas in the prior art mentioned above materials with good thermal insulation and having the ability to avoid clumps are provided by melting the low-melt fibers to the synthetic fibers, the present invention goes a significant step further: According to the invention, the low-melt fibers are melted to natural and / or synthetic down fibers by heating inside the baffle. Thus, such a thermal insulating structure may offer a greater freedom of baffle design compared to using conventional baffles, because bigger baffles or baffles of different sizes and shapes may be used. For example, conventional baffles for jackets just extend horizontally. Therefore, the present invention provides the possibility that smaller baffles for the shoulder regions may be manufactured with bigger baffles in the chest region of a wearer so that the jacket fits closely and tightly to the body of the wearer and may provide improved thermal insulating properties. Alternatively, it is also conceivable that only two baffles may be formed, filled and heated so that the cycle time for manufacturing the jacket may be significantly reduced. Moreover, methods in the prior art create large planar sheets of synthetic insulation while the present invention creates a thermal insulating structure as a 3D structure within the baffle to obtain the optimal thermal and lightweight properties of down clusters.
In some embodiments, the low-melt fibers may be adapted to secure the natural and / or synthetic down fibers inside the baffle. In this case, undesired moving of the natural and / or synthetic fibers inside the baffle may be avoided as the melted low-melt fibers may solidify and may act as binder in order to bond the natural and / or synthetic fibers to each other. Therefore, such embodiments may further improve the thermal insulating properties as the natural and / or synthetic down fibers are evenly distributed over the wearer's body surface.
In some embodiments, the low-melt fibers melted to the natural and / or synthetic down fibers may be adapted to provide a higher thermal insulation per weight compared to synthetic down fibers. In this case, the melted low-melt fibers may provide tiny branches of fibers so that their structure may trap more air molecules per density weight and an increased thermal insulation may be provided.
In some embodiments, the low-melt fibers melted to the natural and / or synthetic down fibers may be adapted to provide a higher dry compression recovery compared to natural and / or synthetic down fibers. As the melted-low fibers are hydrophobic, such embodiments may provide improved recovery properties from a wet state to a dry state compared to other fibers, e.g. natural down fibers, and may still provide, at the same time, excellent thermal insulating properties.
In some embodiments, the low-melt fibers may have been carded with the natural and / or synthetic down fibers into a web structure before heating inside the baffle. Additionally or alternatively, the low-melt fibers may be mixed with the natural and / or synthetic down fibers before carding, e.g. mechanical mixing by a robotic device and / or by hand, and may be blown with compressed air. Using compressed air may give the fiber mixture an ideal loft, e.g. for obtaining a 3D structure. Moreover, the web structure may have been changed from a loose structure to a set 3D structure by cooling the melted low-melt fibers inside the baffle. All of these embodiments follow the same idea of providing improved thermal insulating and lightweight properties as the structure of the fibers may be further optimized in view of trapping air molecules.
In some embodiments, the plurality of low-melt fibers may comprise low-melt core-sheath fibers. Such fibers are well known in the prior art and easy to handle for the heating process inside the baffle. They start to melt before the natural down fibers will be destroyed and / or the synthetic down fibers will start to melt so that a thermal insulating structure may be provided with excellent thermal properties which is also lightweight and durable.
In some embodiments, the plurality of low-melt fibers may be provided as a filament having a linear mass density of 0.1 - 10 dtex, preferably 0.5 - 7 dtex and most preferably 1 - 5 dtex. The inventors have found that such low-melt fibers and filaments provide a good compromise between improved thermal insulating properties and flexibility for further processing, for example for manufacturing garments or duvets.
In some embodiments, the plurality of natural and / or synthetic down fibers may comprise at least one hollow fiber.
Hollow fibers have an internal cavity, which may extend along the hollow fiber and may trap more air molecules. Thus, hollow fibers may further improve the thermal insulating and lightweight properties of the structure.
According to another aspect, the present invention is directed to an article of wear and a sleeping bag comprising an insulating structure according to the invention.
According to still another aspect, the present invention is directed to a method for manufacturing a thermal insulating structure comprising the steps of providing at least one baffle; filling a plurality of natural and / or synthetic down fibers into the baffle; filling a plurality of low-melt fibers into the baffle and heating the fibers inside the filled baffle.
In some embodiments, the method may further comprise the step of mixing the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers before the filling steps. Moreover, the method may further comprise the steps of blowing the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers with compressed air and / or carding the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers into a web structure. Additionally or alternatively, any other suitable medium for blowing the fibers may be applied. Furthermore, the method may comprise the step of disassembling the web structure. Moreover, the method may further comprise the step of cooling the heated filled baffle. These embodiments follow the same idea of providing an optimized manufacture of a thermal insulating structure with improved thermal insulating and lightweight properties.
In some embodiments, at least one of the filling steps may be performed by a robotic device. Such an embodiment may further improve an automation of the whole manufacturing process and thus may reduce the cycle time.
In some embodiments, heating may comprise applying hot air. Moreover, heating may comprise applying electromagnetic radiation. Providing heat energy by heat convection in a gas or the use of radiation may be advantageous as the manufacturing is performed without contact. This means that the filled baffles are not directly touched with the heat source and the manufacturing may be still optimized.
Any method and / or heat source known in the art that can accomplish this may be employed in the inventive method. Examples are the use of radiation (further details on this will follow below), or heat convection in a gas Advantageously, hot air is not expensive, relatively easy to handle and provides the necessary temperature for heating the filled baffle.

4. Brief description of the figures

Possible embodiments of the present invention are further described in the following detailed description, with reference to the following figures, wherein:

Fig. 1:: shows exemplary natural and synthetic down fibers according to an embodiment of the present invention; and
Fig. 2:: shows a thermal insulating structure comprising at least one baffle comprising a plurality of natural and / or synthetic down fibers and a plurality of low-melt fibers according to the invention.

5. Detailed description of preferred embodiments

Possible embodiments and variations of the present invention are described in the following with particular reference to thermal insulating structures such as textiles comprising at least one baffle. However, the concept of the present invention may identically or similarly be applied to any article of wear, covering materials such as duvets or sports equipment such as sleeping bags requiring improved thermal insulation and lightweight properties. The thermal insulating structure according to the invention may be used for a variety of article of wears including jackets, garments with hoods, wherein the thermal insulating structure may be arranged at least in part on the article of wear, may be embedded in the article of wear or may form at least a layer of the article of wear. For example, the thermal insulating structure may be embedded in or form at least a layer of a jacket. In addition, the thermal insulating structure may be embedded at least partially in a tent.
Moreover, for brevity only a limited number of embodiments are described in the following. However, the skilled person will recognize that the specific features described with reference to these embodiments may be modified and combined differently and that certain aspects of the specific embodiments may also be omitted. Moreover, it is noted that the aspects described in the subsequent detailed description may be combined with aspects described in the above summary section.
Fig. 1 shows examples of microscopy pictures of a plurality of natural down fibers 105 and a plurality of synthetic down fibers 150. It has to be noted that any kind of natural fibers can be used such as: wool, kapok, and other seed fibers, leaf fibers, such as sansevieria, fique, sisal, banana or agave, bast or skin fibers such as flax, jute, kenaf, industrial hemp, ramie, rattan, vine fibers, or fruit fibers such as coconut and stalk fibers such as straws of wheat, rice, barley, and other crops including bamboo and grass as well as tree wood and animal fibers such as animal hairs, silk fibers and avian fibers. Moreover, any kind of synthetic fibers can be used such as: Nylon, Modacrylic, Olefin, Acrylic, Polyester, Rayon artificial silk, Vinyon, Saran, Spandex, Vinalon, Aramids known as Nomex, Kevlar and Twaron, Modal, Dyneema/Spectra, PBI (Polybenzimidazole fiber), Sulfar, Lyocell, PLA, M-5 (PIPD fiber), Orlon, Zylon (PBO fiber), Vectran (TLCP fiber) made from Vectra LCP polymer, Derclon used in manufacture of rugs, Acrylonitrile rubber, glass fibers, metallic fibers, expanded polystyrene flakes, urea-formaldehyde foam resin, polyurethane foam, phenolic resin foam.
As can be seen in embodiment 105, the natural down fibers 105 comprise tiny branches 110 extending from the feather staff 120. Again, these tiny branches 110 may trap air molecules and may provide the excellent thermal insulating properties as no heat loss due to the heat conduction occurs. Moreover, this structure may provide a higher density and thus a thicker insulation as well as a lower air permeability so that the thermal insulating properties are further increased.
As can be seen in embodiment 150, the synthetic down fibers 150 are more loosely arranged compared to the natural down fibers 105. The synthetic down fibers 150 may comprise a polyester material which is known under the tradename "3M Thinsulate Featherless II". Other synthetic materials may be also conceivable such as 3M Featherless I, Primaloft Lux, Primaloft Thermoplume, Molina Microrollo, Shinih HaloBall or any other suitable loose fill synthetic fiber as mentioned above and / or insulating material.
Synthetic down fibers 150 can be produced by various techniques, for example by a melt blown process. Such a nonwoven process is unique because it is used almost exclusively to produce microfibers rather than fibers having the size of normal structure fibers. The melt blown process may be a one-step process in which high-velocity air blows a molten thermoplastic resin from an extruder die tip onto a conveyor or take-up screen to form a fine fibrous and self-bonding web. Moreover, the melt blown process is similar to a spun bond process which converts resins to nonwoven fabrics in a single integrated process. The melt-blown web is usually wound onto a cardboard core and processed further according to the end-use requirement. The combination of fiber entanglement and fiber-to-fiber bonding generally produces enough web cohesion so that the web can be readily used without further bonding. In addition, further bonding, e.g. melting to low-melt fibers, and finishing processes may further be applied to these melt-blown webs such as cooling and thus solidifying in a 3D structure. It is also conceivable to implement partially any other suitable extrusion processes.
Summarizing, low-melt fibers melted to synthetic down fibers 150 and solidified in a 3D structure try to mimic the above mentioned structure of natural down fibers 105 for improved thermal insulating properties, but may also avoid clump when they are wet.
Fig. 2 shows an embodiment of a thermal insulating structure 200 comprising at least one baffle 205, e.g. three baffles 205. They comprise a plurality of natural and / or synthetic fibers 210 and a plurality of low-melt fibers 220. The thermal insulating structure 200 may be incorporated into a jacket. Fig. 2 shows a front view of the three baffles 205 in a spatial representation.
The plurality of low-melt fibers 220 inside the three baffles 200 have been melted to the natural and / or synthetic down fibers 210 by heating inside the baffles 205. For example, the low-melt fibers 220 and the natural and / or synthetic down fibers 210 may be filled into the baffles 205, which may be then closed. Closing the baffles 205 may be performed by any suitable method such as sewing, welding, bonding, gluing, etc.
As indicated in Fig. 2, at least one baffle 205, e.g. the right baffle, may be heated by applying a melting agent 230. The melting agent 230 may comprise hot air or electromagnetic radiation. Therefore, the melting agent 230 may penetrate the baffle to melt the low-melt fibers 220 inside the baffle to the natural and / or synthetic down fibers 210. As explained above, hot air is easy to handle for the heating process inside the baffles 205. As another example, an infrared source may provide different wavelengths, for example: near-infrared, short-wavelength infrared, mid-wavelength infrared, long-wavelength infrared and far-infrared, wherein the specific wavelength to be used can be adapted depending on the materials of the low-melt fibers 220 to be melted to the natural and / or synthetic down fibers 210. An advantage of using infrared radiation is thus that it is easy to produce and to apply to the low-melt fibers 220 and to the natural and / or synthetic down fibers 210. The amount of heat energy may, for example, be controlled by adjusting the output power of the source, the intensity of the radiation, the size or emitted wavelength of the infrared heat source, the distances of the source to the materials, the view factor of the baffle's surface, i.e. how much of the emitted energy the baffle's surface receives, or the emissivity of the baffle's surface material, etc. Moreover, the use of infrared radiation does not impose any particular requirements, such as electrical conductivity, on the material of the fibers. It is therefore particularly suited for melting the low-melt fibers 220 to the natural and / or synthetic down fibers 210.
In the embodiment of Fig. 2, the baffles 210 comprise a baffles box construction structure. The skilled person in the art will recognize that the concept of the invention may be also used for natural and / or synthetic fibers 210 melted with low-melt fibers 210 inside other construction designs such as pockets, small boxes, sewn through baffled box design or stitch-through baffled box design.
In one embodiment, the low-melt fibers 220 may be adapted to secure the natural and / or synthetic down fibers 210 inside the baffle 205. This can be enhanced by adding an adhesive to the low-melt fibers 220.
In one embodiment, it is also conceivable that one baffle may comprise a different amount of low-melt fibers than another baffle. For example, if the baffles 205 will be used for a sleeping bag, some regions may provide better thermal insulation than other regions. It is also conceivable that some regions may be stiffer than other regions in order to imitate or support a sleeping mat. This can be achieved by a higher amount of low-melt fibers 220.
In the embodiment of Fig. 2, the low-melt fibers 220 have been carded with the natural and / or synthetic down fibers into a web structure before heating inside the baffle. Moreover, the web structure may change from a loose structure to a set 3D structure by cooling the melted low-melt fibers inside the baffle.
In one embodiment, the plurality of natural and / or synthetic down fibers may comprise at least one hollow fiber. Hollow fibers can be produced by various techniques, for example by a wet spinning process. In such a process, the fiber is made from a solution of a polymer, e.g. from a solution of polyamide, by extruding the solution through a spinning nozzle around a central fluid.
In the following, further embodiments are described to facilitate the understanding of the invention:

1. A thermal insulating structure (200), preferably a thermal insulating textile, including at least one baffle (205), the baffle comprising:
1. a. a plurality of natural and / or synthetic down fibers (210);
2. b. a plurality of low-melt fibers (220);
3. c. wherein the low-melt fibers (220) have been melted to the natural and / or synthetic down fibers (210) by heating inside the baffle (205).
2. The thermal insulating structure according to the preceding embodiment, wherein the low-melt fibers are adapted to secure the natural and / or synthetic down fibers inside the baffle.
3. The thermal insulating structure according to any of the preceding embodiments, wherein the low-melt fibers melted to the natural and / or synthetic down fibers are adapted to provide a higher thermal insulation per weight compared to synthetic down fibers.
4. The thermal insulating structure according to any of the preceding embodiments, wherein the low-melt fibers melted to the natural and / or synthetic down fibers are adapted to provide a higher dry compression recovery compared to synthetic down fibers.
5. The thermal insulating structure according to any of the preceding embodiments, wherein the low-melt fibers have been carded with the natural and / or synthetic down fibers into a web structure before heating inside the baffle.
6. The thermal insulating structure according to the preceding embodiment, wherein the web structure has been changed from a loose structure to a set 3D structure by cooling the melted low-melt fibers inside the baffle.
7. The thermal insulating structure according to any of the preceding embodiments, wherein the plurality of low-melt fibers comprises low-melt core-sheath fibers.
8. The thermal insulating structure according to any of the preceding embodiments, wherein the plurality of low-melt fibers is provided as a filament having a linear mass density of 0.1 - 10 dtex, preferably 0.5 - 7 dtex and most preferably 1 - 5 dtex.
9. The thermal insulating structure according to any of the preceding embodiments, wherein the plurality of natural and / or synthetic down fibers comprises at least one hollow fiber.
10. An article of wear comprising a thermal insulating structure according to any of the preceding embodiments.
11. Sleeping bag comprising a thermal insulating structure according to any of the embodiments 1-9.
12. A method for manufacturing a thermal insulating structure comprising the steps of:
1. a. providing at least one baffle;
2. b. filling a plurality of natural and / or synthetic down fibers into the baffle;
3. c. filling a plurality of low-melt fibers into the baffle; and
4. d. heating the fibers inside the filled baffle.
13. Method according to the preceding embodiment, further comprising the step of mixing the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers before the filling steps.
14. Method according to one of embodiments 12 or 13, further comprising the step of blowing the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers with compressed air.
15. Method according to one of embodiments 12 - 14, further comprising the step of carding the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers into a web structure.
16. Method according to the preceding embodiment, further comprising the step of disassembling the web structure.
17. Method according to one of embodiments 12 - 16, further comprising the step of cooling the heated filled baffle.
18. Method according to one of embodiments 12 - 17, wherein at least one of the filling steps is performed by a robotic device.
19. The method according to one of the embodiments 12 - 18, wherein heating comprises applying hot air.
20. The method according to one of the embodiments 12 - 19, wherein heating comprises applying electromagnetic radiation.

Claims

A thermal insulating structure (200), preferably a thermal insulating textile, including at least one baffle (205), the baffle comprising:
a. a plurality of natural and / or synthetic down fibers (210);

b. a plurality of low-melt fibers (220);

c. wherein the low-melt fibers (220) have been melted to the natural and / or synthetic down fibers (210) by heating inside the baffle (205).
The thermal insulating structure according to the preceding claim, wherein the low-melt fibers are adapted to secure the natural and / or synthetic down fibers inside the baffle.
The thermal insulating structure according to any of the preceding claims, wherein the low-melt fibers melted to the natural and / or synthetic down fibers are adapted to provide a higher thermal insulation per weight compared to synthetic down fibers.
The thermal insulating structure according to any of the preceding claims, wherein the low-melt fibers melted to the natural and / or synthetic down fibers are adapted to provide a higher dry compression recovery compared to synthetic down fibers.
The thermal insulating structure according to any of the preceding claims, wherein the low-melt fibers have been carded with the natural and / or synthetic down fibers into a web structure before heating inside the baffle.
The thermal insulating structure according to the preceding claim, wherein the web structure has been changed from a loose structure to a set 3D structure by cooling the melted low-melt fibers inside the baffle.
The thermal insulating structure according to any of the preceding claims, wherein the plurality of low-melt fibers comprises low-melt core-sheath fibers.
An article of wear comprising a thermal insulating structure according to any of the preceding claims.
A method for manufacturing a thermal insulating structure comprising the steps of:
a. providing at least one baffle;

b. filling a plurality of natural and / or synthetic down fibers into the baffle;

c. filling a plurality of low-melt fibers into the baffle; and

d. heating the fibers inside the filled baffle.
Method according to the preceding claim, further comprising the step of mixing the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers before the filling steps.
Method according to one of claims 9 or 10, further comprising the step of blowing the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers with compressed air.
Method according to one of claims 9 - 11, further comprising the step of carding the plurality of natural and / or synthetic down fibers and the plurality of low-melt fibers into a web structure.
Method according to the preceding claim, further comprising the step of disassembling the web structure.
Method according to one of claims 9 - 13, further comprising the step of cooling the heated filled baffle.
Method according to one of claims 9 - 14, wherein at least one of the filling steps is performed by a robotic device.